A three-phase axisymmetric numerical model based on Volume of Fluid–Continuum Surface Force (VOF–CSF) model was developed to perform parametric analysis of compound droplet production in three-phase glass capillary devices that combine co-flow and countercurrent flow focusing. The model predicted successfully generation of core–shell and multi-cored double emulsion droplets in dripping and jetting (narrowing and widening) regime and was used to investigate the effects of phase flow rates, fluid properties, and geometry on the size, morphology, and production rate of droplets. As the outer fluid flow rate increased, the size of compound droplets was reduced until a dripping-to-jetting transition occurred. By increasing the middle fluid flow rate, the size of compound droplets increased, which led to a widening jetting regime. The jetting was supressed by increasing the orifice size in the collection capillary or increasing the interfacial tension at the outer interface up to 0.06 N/m. The experimental and simulation results can be used to encapsulate CO2 solvents within gas-permeable microcapsules.
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机译:建立了基于流体-连续体表面力体积(VOF-CSF)模型的三相轴对称数值模型,以对并流和逆流聚焦相结合的三相玻璃毛细管装置中的复合液滴产生进行参数分析。该模型预测了滴加(缩窄和加宽)状态下核壳和多核双乳液液滴的成功生成,并用于研究相流速,流体性质和几何形状对尺寸,形态和结构的影响。液滴的产生率。随着外部流体流速的增加,化合物液滴的大小会减小,直到发生滴落到喷射的过渡为止。通过增加中间流体流速,化合物液滴的尺寸增加,这导致喷射范围扩大。通过增加收集毛细管中的孔口尺寸或将外界面处的界面张力提高到0.06 N / m,可以抑制喷射。实验和模拟结果可用于将CO2溶剂封装在透气微胶囊中。
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